DE2023692C3 - - Google Patents

Description

20 23

number of electroluminescent picture elements with respect to applied voltages of any polarity

knows, where crossing row and column lines switch below an upper threshold voltage

ter are present, at whose intersection points, however, when a voltage of any polarity is applied

Light elements are arranged. In this picture above the upper threshold tension from the access

playback device is connected to the line conductors one after the other with high resistance in a state of low

which laid the operational potential. The column conductors have resistance. This change will take place after

all hold a video signal information at the same time, a timing device

mation according to the brightness of the display delay, although the switching process

coming picture line. The lighting element is initiated, essentially instantaneously

an energized line will be idle at the same time. The semiconductor threshold switching elements

state, while the operating potentials automatically return to their state of high return.

tial is placed on the next line. Stand back when the current flowing through it

From the DT-AS 10 72 650 a device is used to drop below a minimum holding current close to zero. Playback of images with a variety of through The threshold switching elements have immediately after an energy source fed, light-emitting 15 switching to the non-conductive state a we-Budelemente known, at which the brightness control significantly reduced threshold voltage. The standard takes place by means of transfluxors, which is based on the energy male, the original threshold voltage flow from the energy source to the picture element corresponds to a relatively short time delay Reduce the brightness to the desired level. The recovery during which the threshold light duration of the picture elements is constant. 20 voltage increases progressively, reached again.

In the older German patent 17 62174 semiconductor materials are proposed for the construction of such, the luminous elements with a single threshold switching elements can advantageously be of the type described in the patent ..., excite with a direct current pulse of constant amplitude. The length of this direct current pulse is SR Ovshinky, (patent application), depending on the desired brightness. a ₅ chcnd of U.S. Patent 32 71 591

The present invention aims to be. By modifying the basis of the semiconductor combination, a circuit arrangement of the above reference or the treatment of the above handle of the claim specified type, patent specification described material, it is possible the line-by-line excitation of the light elements creates the upper and lower threshold voltage, which enables blocking and in which the brightness control by 30 or leakage resistance and that of the device are own Control of the lighting duration of the lighting elements easily adds time delay values in this way he follows. vary so that the desired range of conditions

The solution to this problem is given by the conditions that can be achieved for those who do not work properly Features of claim 1. ability of electroluminescent matrix systems ge

Briefly speaking, the invention provides that a measure of the invention is required.
It has been found that the inherent application of an operating potential to the selected shafts of the above type of row of electroluminescent elements by threshold switching elements have unexpected advantages when they are used for the row circuit line during each column switching presentation of video signal information used line receives a video signal information, which is 40. A peculiarity inherent to the elements due to the electroluminescent circuits along the line is of particular importance that a variable of the selected row connection lines to under- time delay between the point in time are excited at different points in time, so that the threshold switching elements a threshold voltage is applied from the Einielbildelemente along the line and the point in time at which the threshold switching line of light of different intensity 45 switching elements is actually emitted from their blocking state. The operating potential applied to the selected row switching high resistance line in its conductive state is switched over with the same low resistance, but eliminated early, whereby all picture elements are excited practically instantaneously along this line due to this switching. Then the next row circuit line is excited within nanoseconds, for example, and the switch-on delay of these elements is, however, supplied to the video information. This advance with changes of the over the threshold voltage of the gang is repeated line by line, so that finally relevant elements also applied voltage the whole pattern or picture to be presented is formed changeably. An increase in tension from the will. If the speed of this line-by-line threshold voltage from scanning the electroluminescent device to a higher voltage causes a reduction in the value of the element selected so that it exceeds the speed of conventional switch-on time delay. If, therefore, a voltage pulse is applied to the blanking elements sent out by television transmitters, the signals of which correspond, a conventional television picture can be fenden elements or larger by means of the electrolumines- amplitude equal to the threshold voltage of the arrangement in question, but which can be reproduced during. 60 lasts a period of time that is less than

The switching elements used according to the invention are the elements of their own and that of the relevant span elements are single-layer threshold semiconductor device amplitude associated time delay, see above Lines with essentially the same conductivity, the threshold switching element is not in the conductive opposite applied positive and negative live state. On the other hand, if the nings. In comparison to one another, however, they can have an amplitude-dependent threshold switching element different threshold voltages gnal is supplied, which the switching element own to have. The threshold switching devices have time delayed this, at a time start a very high electrical resistance to become point-conductive, which depends on the amplitude of the

applied signal is determined. So when the threshold circuit or image used in accordance with the invention is presented to the section of a video pattern to be presented. The electroluminescent as operating potential an alternating voltage zente arrangement, a certain number of is applied, the frequency is high enough, so row and column circuit lines in X- V-Madaß the periodic pulses have a duration, 5 trix arrangement with formation of a switching point at each is shorter than that of the element and the line lines corresponding to the intersection of the column and row scarf amplitudes of the applied voltage. At each of the switching points time delay, a voltage exceeding the threshold voltage can be applied to the switching element, which can be activated by means of a threshold switching element, without the conductive electroluminescent circuit becoming any such threshold-dependently operated electroluminescent circuit. Minescent circuit advantageously has a

Another one with the largest non-directional sleeper shaft element in the invention Advantageously, threshold switching elements used time delay properties, a luminous element own peculiarity is their own time delay and a resistance on. There are institutions tion in the restoration of the original, 15 provided, which make it possible to attach to each of the line normals Threshold voltage after switching off the circuit lines one after the other an operating potential element as a result of the decrease in current strength to be applied below tial. Even if any given the minimum holding current. This means that after the line circuit line is energized, each of the on-toggles remains of the switching elements in a substantially sealed electroluminescent circuit There is a reduced threshold voltage, which, however, remains in a stable off state until a start signal is applied to each of the columns increasing the time until the original, normal circuit lines. Value increases. Therefore, if within the period of time only then will the electroluminescent switchover Time delay in the restoration, the conditions that end at the switching points of the selected row Switching a threshold switching element in and column switching lines are connected, the non-conductive state follows, stimulated to this EIe 25 to emit light. The light intensity of If a voltage pulse is applied, each of the selected rows needs the amplitude this impulse only hangs like the then prevailing electroluminescent circuits see momentarily lower threshold voltage from the point in time in which the light emission in to be to the threshold switching element again lei- activity is set. Preferably all close. 30 borrowed electroluminescent circuits along the

If the row selected on the threshold switching element is de-energized at the same time, in that the occupied operating potential is an alternating voltage of the driving potential of the row circuit line of the opposite frequency, so that each of them is switched periodically. The next line then receives successive pulses within the operating potential for the circuit line, so that it can display video information on the other hand, in full restoration of the original.
Time delay required for threshold voltage In the drawing, a schematic representation of these switching elements is shown at each halving of an embodiment of the invention and the periodc of the applied voltage is made continuously conductive according to the characteristic curves explaining its function, even if the applied voltage is essential.

Hch lower than the normal, original 40 F i g. 1 is a simplified block diagram of a

Threshold voltage. electroluminescent presentation system with a

By using the switch-on time delay circuit arrangement according to the invention;

of the above threshold switching elements and FIG. 2 is a diagram for illustrating the

Time delay in restoring its original circuit components of an electroluminescent

abrupt threshold voltage, numerous 45 circuits can be found on each light element of the electrical

surprising advantages can be achieved. The emergency luminescent arrangement according to the invention

ability to use a variety of threshold switching elements;

th with essentially the same threshold F i g. 3 is the current-voltage characteristic

lens voltage is switched off, since the threshold switch used in the invention

effective and reliable operating range of these 5 ° elements;

Switching elements (the tolerance range) with increasing F i g. 4 is a graphical representation of the timing

Frequency of the applied operating potential is essentially the same as that used in the invention

loaned is increased. All of these switching elements allow threshold switching element to be inherent;

readily appear on the large scale as films or thin figs. 5 is a graphical representation of the timing

Produce layers with planar layers by delaying the restoration of the original

gen surfaces made of electroluminescence threshold voltage, which corresponds to the invention

material are in contact, so that the possibility of turned threshold switching element is inherent;

consists, flat and relatively thin image F i g. 5 a is a diagram for illustration

to manufacture umbrellas. the relationship between the frequency and the

The invention therefore provides a circuit arrangement 60 for the threshold voltage used in the invention for line-by-line excitation of the individual luminous elements; and
elements of the electroluminescent arrangement in sol- F i g. Fig. 6 is an illustration of a series of ways in which each individual luminous element is excited along a period of time to illustrate the operation of a selected row during different other electroluminescent circuits, so that a plurality of given row circuit lines of electroluminescent light intensities are generated. Detergent .YV arrangement for generating the through, a gray scale gradient is achieved on the desired changes in the light intensity of the selected line, so that a single scan line of individual electroluminescent switching

the selected line to create a gray scale. After line 17 is fully aroused, will

for the device according to FIG. 1 generated them quickly shut down and the operational potential

Presentation sample or image. is fed to the next row line 18, while

F i g. 1 shows a simplified form of a new video signal information in the video system, which is used to operate an electrolu 5 signal information converter with parallel output 30

minescent arrangement according to the principles of being stored and processed. Then the

Invention can be used. A control switch video signal information to the column switch

device is generally designated 10 and is used to put lines 22 to 27, so that all lighting

Actuation of an electroluminescent XY-Ma.- elements along the line circuit line 18 antrix arrangement 12, controlled by a video io are excited. This process is quickly repeated

Signal information receiver 14. The video signal fetches until all the line interconnection lines are energized

Information receiver 14 can be a conventional remote and a complete "frame" or a

be a visual receiver and the corresponding video image is formed from the video signal information.

gnalinformation and synchronizing pulse signal information after energizing the last row circuit line mation for the line-by-line actuation of a multiple 15, the process is repeated automatically so that a

number of electroluminescent circuits 16 or another "frame" or another image from Vi

long a given one of a plurality of line deo information is formed. In this way

Supply circuit lines 17, 18, 19, 20 and 21. can quickly change presentations or images

The video signal information is transmitted to a plurality of the electroluminescent device 12 in over of Column circuit lines 22, 23, 24, 25, 26, 20 in accordance with the video signal information

and 27 laid out in parallel. In this case, facilities are presented to a television receiver

intended to be the excitement of each luminous.

elements along the selected line according to FIG. 2 shows the circuit components of an electroluminescence used to delay the amplitude of the supplied video signal information of the invention in such a way that each luminous element 25 th circuit. The electroluminescent circuit 16 is only excited for a period of time which the amplitude has a resistance 35 which corresponds to a span or the relative brightness of the signal to be presented for the amplitude and time delay thresholds. Switching device 36 is connected, which in turn is connected to a luminous element 37 for the operation of the electroluminescent arrangement. It is to note 12 according to the invention is preferably a 30 note that both the circuit arrangement geOszillator 28 with gate circuit (gated oscillator) pre-measured F i g. 2 is shown as a series circuit, which is seen from the video signal information emp- invention in the broadest sense all with this catcher 12 synchronization signals via a line 29 components possible circuits for emitting that operate the oscillator 28 in such a way that ren of light according to a selectively supplied lines 17 to 21 at a rate of 35 th video signal information. The lights are excited one after the other, the vertical ab- ment 37 acts in the circuit as a capacitor, sweep speed, for example when the threshold switch element 36 becomes conductive, corresponds to a television set. A video signal in- is fed to the electrode 37 α charge. When the formation converter and a circuit with par- amperage of the through the threshold switching element

"* *" »Λ receives video signal information 40 36 flowing current below a minimum holding current

■ '- ^: -'"Increases the charge on electrode 37 α

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Light elements 16, jiij> «f _a different swing j ; * _{Ducks Saddle} itung about those who cherish line 17 is "^ _{n, in} activity overall £ ^ he elec _{erwejse mk capacitive mJ}

elements that during aer 1 « b _{h and} d, e ^ ¹ ™ ^«: "3 4 5 and 5 a the different eleV

are excited, emit the ^ brightest £ _time . _c hen the F i | g.3, 4 ^ una _haUekment

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th between the blocked state and the conductive state, however, if the maximum value of the applied Wechkeitstatus takes place - after the precharge voltage has elapsed beyond the threshold voltage tion own time delay - extremely fast. increases, the element is practically instantly ge-Fig. 3 is a current-voltage curve for measuring curve sections 41-41 in its control diagram of the alternating current operation of the threshold state switched over by the curve switching element 36, it should be noted that sections 42-42 are illustrated. This by-product Applying a DC voltage only the first or switching takes place during each half cycle of the angcnur only the third quadrant alone applies. Assuming that the alternating voltage is applied. If the created exchange, the at the Schweilenschaltelement 36 a self voltage approaches the value of zero, so that the DC voltage is applied, as in the first qua ίο current through the welding switching element 36 below 3 illustrates, if it is the minimum holding current value falls, it switches according to normally in its locked state with high the curve sections 43-43 from the low electrical state Resistance. Curve 40 illustrates the electrical resistance in the holicht state the current-voltage characteristic of the element electrical resistance, which is caused by the tes when increasing the DC voltage. It blocks 15 curve sections 40-40 is illustrated. the element essentially allows current to pass through. Fig. 4 illustrates the threshold switching

If the voltage is increased up to a threshold voltage element 36 of its own turn-on time delay, the electrical resistance of the characteristic decreases. In this figure, the normal threshold semiconductor materials are practically instantaneously in voltage at V ₇ and the device's own at least one path through the semiconductor material, 20 time delay in the threshold voltage at T _d that forms the threshold switching device 36, is indicated by. The change in time delay is its high value to a low value. This is shown by curve 45. The threshold switching is essentially instantaneous. In this way a conductivity feed becomes conductive. This period of time is inversely formed in relation to the low electrical resistance, proportional to the applied overvoltage, such as when current can flow through the element. Which the curve 45 is illustrated. The values of the time-low electrical resistance is several toe-delayed and the threshold voltage can be changed in powers of less than the high electrical resistance, among other things, by changing the to-resistance. The conductivity state is illustrated by the composition of the threshold curve section 42 for building. It can be seen that the semiconductor material used in the switching elements 36 changes a substantially linear current or the thickness of the layer or the film which forms the curve at a substantially constant voltage. It is noted, however, that the time delay 7 " _rf is the same for increasing and decreasing current. In other words, the current conduction increase in the applied voltage between V ₇ takes place at an essentially constant voltage. And V ₁ , The duration of the haloconductor material forming the low resistance state of the voltage switching element 36 connected to the threshold voltage switching element 36 therefore only needs to be as long as the time causes a voltage drop, which is only a small delay in the case of the voltage excess V ₇ corresponds to the voltage drop in the blocked state.

hen resistance is. F i g. 5 illustrates the threshold switching

When the voltage is decreased, the element 36 inherent time delay T _(l in the current along curve 42 decreases, and when the current restoring the original thresholds falls below the minimum current holding value, the 45 voltage increases after switching back to the non-conductive electrical resistance of the conductive path or This time delay is illustrated by the curve of the paths through the semiconductor material quickly of 46. From this curve it can be seen that the value has returned from the low to the high value, as this is illustrated immediately after the threshold switch is illustrated by curve at: , so that element 36 has become non-conductive. The threshold that the blocking state with high resistance is again substantially reduced so that this is established. In other words, however, the threshold voltage increases with time until pressed, a minimum holding current required to achieve the normal threshold voltage V ₇ again ht welding element 36 is in its conductive closed. The time delays can easily be impacted to withstand. The threshold voltage of the threshold voltage, among other things, because the composition of the switching element is, however, immediately after the semiconductor material used has been changed and it has become non-conductive, significantly reduced. of voltage pulses, for example a change to their normal value, the original self-voltage or a pulsating direct voltage, threshold voltage. is operated, only the introductory chip

In the event that an amplitude and a duration of 36 an alternating voltage is applied to the welding switch element 60, the current-voltage curves of both quadrants 1 and the time delay according to F i c apply to the original threshold voltage. . 4 or one and 3 of Figure 3. Here, there is the emerging of the overvoltage "the pulse associated clotting switching element 36 in its locking state when the Geren time delay corresponding to W:. Then nn a maximum value of the applied AC voltage nied- 6 ₅ subsequent voltage pulse to . is the threshold Riger than the threshold voltage of the element-switching element 36 is brought into effect before the Speit state is indicated by the curve portions, it has been fully recovered, that is, the normal, ur-40-40 in two quadrants 1 and 3 illustrates _s;. üngliche Schwellcnspannung V ₇ (Fig. 4) again-

11 12

is established, this next voltage in the circuit line 17, an alternating voltage 50 pulse, only needs to have an amplitude which is the same as that applied to (FIG. 6) and is none of the threshold voltage then prevailing, the two circuit 16 along the line circuit for example , depending on the point in time at which night 17 is excited. However, when a video signal is applied in the first voltage pulse, the 5 pulse on each of the column circuit lines 22-27 can range between 0.01 V _T and V ₇ . Which is applied, enters the electroluminescent circuit in FIG. 4 illustrated switch-on time delay at the switching points as a function of a time can persist regardless of the point in time at which the delay in action, which corresponds to the size of the video information to be brought to the next voltage pulse of the threshold switching offer, element 36 is maintained, whereby the io if the relative brightness of each is the only difference in a shift of the gantroluminescent circuits 16 in ten equal zen curve 45 downwards, as is shown by the range of curves 45a divided in broken lines by the brightness intervals or brightness level, which is denoted by ß, - ^ io (Fig. 6) are illustrated. According to the invention, a video pulse can be correct at any one of these threshold switching elements, once they are conductive 15 valle the degree of brightness that has been made with the electrolumines, by means of a single circuit at the switching point of the row formers following pulses with a voltage amplitude line 17 at close intervals and any column scales lower than the original normal threshold line 22-27 is reached. So if there is a voltage in the switching element, video pulse 52 is continuously switched to a selected column. However, if the applied line 22 to 27 is applied, for example voltage, ie the direct voltage or alternating voltage during the interval B ₇ , the brightness is voltage pulses during a period of time corresponding to the selected electroluminescent circuit 16 Device own time delay 70%> of the total brightness, which is achieved by applying the restoration according to FIG. 5, interrupted all pulses within the wave packet that is being reached, the threshold switching element 36 25 containing the sine wave pulses 50 would be reached, that is, the original While the electroluminescent circuit 16 is energized normal threshold voltage of the device is full, is the voltage change at which the lamp is constantly being restored. The device ment essentially a DC voltage which is varied by the voltage whose amplitude is lower than a zero reference line 54. The voltage as the threshold voltage of the threshold switching device across the entire electroluminescent circuit is no longer conductive. In Fig. 5 A is but it can be a variable DC voltage, the relationship between the threshold voltage and the frequency for the threshold switching element 36 because the AC voltage applied to the line 17 and the curve 47 applied to one of the lines 22 to 27 illustrates. Because of the Zeitverzö- video pulse are combined, as by the variable DC voltage 50 a voltage threshold, the switching element operates within indicated delay in restoring the Schwellenspan- 35th If, on a selected column of a bistable operating range, regardless of circuit line 22 to 27, a video signal is applied to the type of load or circuit arrangement and the selected electroluminescent device to which it is connected. So if the threshold circuit makes conductive during a shorter time period switching element 36 in conjunction with a capacitive 40 span, for example in the time inverse resistor is used, which also has a interval B., then that of the electroluminescent bistable operating range, they create Combined circuit 16 emitted light so far reduced that niertcn bistable properties of the device with it is only 50 ⁰ O of the total light emission of the capacitive resistance, here an electroluminescent light element during the interval, central element, in conjunction with the bistable 45 if Both an operating potential and a Vitricbs range of the threshold switching element a video signal is applied to the selected circuit line with the significantly expanded bistable operating range. The smallest amount of light emitted by one with an increase in frequency. The extent to which the resulting electroluminescent circuit 16 can be extended to the bistable range of an electroluminescent circuit is that which is represented by the brightness- _{dispensing circuit according to the invention increases 50 gel B 1} , in which only a single number increases with increasing difference between the original pulse of the alternating voltage to the light element 3 "and the normal threshold voltage that is applied. The greatest possible brightness that can then be obtained from a light element 37 can be obtained by increasing the distance. This is achieved by increasing the distance is achieved by applying a video pulse: between the elongated thin line on 55 of one of the column circuit lines 22 to 27 zii: level V ₇ and curve 47 in FIG. 5 A at the same time as the displayed light. applied operating potential to the selected rows by forming an electroluminescent switching circuit line angel is determined, so that the entire circuit using the time interval described above, or the entirety of the pulses within the threshold switching element, can therefore generate the electroluminescent 60 of the wave packet, to excite the luminous minescent arrangement 12 according to FIG. 1 is used in a new element 37. So by operating the electrolu-like and unique way. minescent arrangement 12 according to the invention and according to the invention, a continuously applied operating potential is operated according to the illustration in FIG 65 signal information on the vertical column circuit line, can be viewed, is applied sequentially to lines 22-27, while applied to a row circuit lines 17-21. Selected row circuit lines 17 to 21 eil, for example, can be applied to the row operating potential in an instant, from each of the electro

luminescent circuits 16 different light intensities can be obtained. The line switching elements-; 36 needs to be considered _n those

follows whereby an entire video image is formed

Video signal information is recorded by the video signal automation receiver 14, which can be a conventional part of a television receiver, and is processed in it in the usual way. Oscillator with gate circuit causes ₅ then the application of an operating potential to a selected Zfilenschaltungleitung, for example the line 17, during a period which corresponds to the sampling period of a conventional television receiver. When the operating potential applied to a selected flyback line is an AC voltage, as shown here, the length of time between pulses is selected to be within the time delay inherent in the threshold switch element 36 in restoring the original threshold voltage. In this mode of operation, the threshold switching element 36 basically acts as an isolating device, which isolates all lighting elements against excitation until a suitable video control pulse is applied, whereupon all the pulses still contained in the package of operating potential are applied to the lighting element 37 without the original, normal threshold voltage of swelling from one line to the

ment to ^^ ÄÄ3 so that the gray level scale is found, which is necessary to bring television pictures on a flat screen with ^^^ Ζ ^ Τηί . The simultaneous termination of the noise

supply of all f ^? ^^
a given flyback line
Invention represents ^e »« ^^^ J ^
Adjustment of the g

nen time delay. the restoration of the threshold voltage, since a given cell circuit line during a, single image of the V.deoinformat.on to be presented only once mn the operating potential to be excited

Through the use of threshold switching elements with the electrical Properties unite with an electroluminescent Circuit arrangement in which the light-emitting element acts as a capacitor and when operated a plurality of such electroluminescent circuits according to the invention can be used to achieve a gray scale that is essentially the gray scale video information to be presented corresponds to a variety of different light intensities are generated.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. Circuit arrangement for luminosity control at least one light emitting Luminous element, in particular for a flat television screen, with one for exciting the Luminous element serving pulse voltage source, the pulses of which are independent of the respective desired luminous intensity are formed, and with one for controlling the luminous intensity of the luminous element Serving control voltage source, the pulse voltage source or the light element is in control connection, characterized in that the pulse voltage source (14) repeats a certain number of times of pulses (50; 50 α) generated in a predetermined period and that the luminous element (37) of this, in each given period of time, one dependent on the control voltage, the Luminosity-determining number of pulses received. 2. Circuit arrangement according to claim 1, characterized in that a first group (17 to 21) and a second group (22 to 27) of circuit lines arranged in such a way to one another are that they form switching points (16), the number of which is the number of individual points of the electroluminescent The arrangement corresponds to the fact that a luminous element (37) and a threshold switching element (36) is connected between each of the switching points (16) that each of the threshold switching elements (36) at a predetermined threshold voltage value after its own switching delay becomes conductive that the pulse voltage source (14) to the first group (17 to 21) circuit lines is placed, the pulse voltage below the value of the threshold voltage of the threshold switching elements (36) is that the control voltage source from the video signal controlled voltages to the second group (22 to 27) of circuit lines leads to an increase in voltage above the threshold voltage of the connected Threshold switch (36) for energizing the luminous elements (37) during a period of time, which corresponds to the brightness of the video information to be presented, and that a device for selectively terminating the conductivity of all threshold switching elements (36) is provided along a selected circuit line of the first group (17 to 21). 3. Circuit arrangement according to claim 1 or 2, characterized in that a device to delay the voltage controlled by the video signal by a period of time that a function of the amplitude of the video signal information is provided. 4. Circuit arrangement according to one of claims 2 to 3, characterized in that the Switch-on time delay that is inherent in each of the threshold switching elements (36), the point in time determined at which the luminous element (37) emits light in accordance with the video signal information. 65 The invention relates to a circuit arrangement eemäß preamble of claim 1 Arrangements for the presentation of information in the form of panels or plates are known, in particular two-dimensional performance yornchtuneen for the visual reproduction of electronic video signals, and methods and apparatus for Controlling such arrangements. The subject of the invention is in particular the excitation of a multiple number of luminous elements along a given Ze.le at points in time corresponding to the amplitude of the in the relevant individual row line for display upcoming video information. All light elements are finally extinguished at the same time, so that a gray scale is created that it the Electroluminescent arrangement allows rapidly changing video signal information for the performance bring to. Heretofore, the development of two-dimensional performance type electroluminescent matrices has encountered numerous problems. Some of these problems result from certain minimum requirements that must be met in order to ensure reliable excitation and de-excitation of the individual light points. Some of these requirements are as follows: The light element must be controlled in accordance with the stored video signal information; the switching device used to control the luminous element must have a sharply defined threshold voltage. The tolerance for the threshold voltage of a large number of threshold switching devices must be very tight. In addition, the luminous elements must have low energy consumption and be suitable for mass production in geometric shapes that can be easily built into display panels such as flat panel displays. A known type of construction for an electroluminescent display panel is the cross-grating or the XY type. The electrodes of this type of construction, which are arranged in parallel, are divided into strips and aligned at right angles to one another. Although such tables are generally based on a Cartesian coordinate system, they can also be constructed on a polar coordinate system or some other system, if desired. In this type of display panel, an alternating voltage is applied between the selected X and Y cross grid lines to excite the electroluminescent element at their intersection. In practice, such Xy display panels of this type have numerous such switching points, each of which represents a connection device for a luminous element for the formation of a point in the electroluminescent arrangement. The excitation of selected luminous elements would enable the presentation in front of television images or other information patterns or numbers. However, numerous problems are encountered in attempting to generate or reproduce images on A'-F display board type screens. The need to apply operating potentials one after the other to successive rows or columns in order to excite the individual luminous elements one after the other, has zui consequence that because of the capacitive cross coupling in this arrangement, undesirable luminous elements are also excited. From FR-PS 15 47 955 an image display device is used to control the excitation of a large amount